Non-lytic, non-ionic detergent extraction of plasma membrane constituents from normal and transformed fibroblasts.

A technique has been developed for the selective extraction of plasma membrane protein constituents from normal and transformed cell employing non-ionic detergents. The extraction procedure does not damage cells as judged by cell viability, 51Cr release, and trypan blue staining. Lactoperoxidase-catalyzed iodination followed by detergent extraction permits demonstration of a 100,000 dalton protein which is found on the surface of normal but not transformed hamster and mouse fibroblasts.     

Agglutination of Normal Cells by Plant Lectins following Infection with Nononcogenic Viruses

MAMMALIAN cells transformed by oncogenic viruses and chemical carcinogens undergo characteristic changes in their surface properties, some of which affect the control of cell multiplication. Certain plant lectins agglutinate transformed cells but not normal cells^1–6, which, although possessing binding sites, can only be agglutinated following treatment with proteolytic enzymes^3–5. Furthermore, both normal and transformed cells bind equal amounts of lectins, indicating that the increased susceptibility of transformed and trypsinized cells to agglutination is not caused by simple “unmasking” of hidden receptor sites. Nevertheless, the increased susceptibility of normal cells to agglutination following trypsinization may well result from changes occurring in the cell coat material. Since lytic infections with certain nononcogenic viruses¹⁰ and various drug treatments¹¹ are known to cause modification of the coat material in normal cells, we were interested to see whether these treatments increased the susceptibility of cells to agglutination by lectins.     

Human p53 and human tumours

In normal human cells, a protein with a molecular weight of about 53,000 (p53) is present at a low level, detectable only by sensitive assays. When the cells are infected with some DNA tumour viruses or transformed by the same viruses, the amount of this protein increases dramatically, and much of it is found in a physical association with the virus-coded protein that causes the transformation. The increase in amount and, incidentally, stability of p53 is not peculiar to virus-transformed cells, but also occurs in cells transformed by chemicals or radiation where there is no sign of any virus being involved (reviewed by Crawford).¹ Cells in culture are not the same as cells in a patient, but these observations do raise questions about the possible involvement of p53 in human tumours.     

Incorporation of [14C]-2 deoxy-D-glucose into the lipids of normal cells as compared to virus-transformed cells

[¹⁴C]-2 deoxy-D-glucose is incorporated into the glycolipids of both normal and transformed cells. The chromatographic pattems of [¹⁴C]-2 deoxy-D-glucose labeled lipids differ markedly in oncornavirus and herpes simplex virus-transformed cells as compared to normal and virus-infected but not transformed cells. Deoxyglucoselabeled lipids with intermediate chromatographic mobility were enriched in normal and virus-infected but not transformed cells. Studies with a murine sarcoma virus-infected cell line which is temperature-sensitive for transformation indicated that the altered chromatographic pattern of [¹⁴C]-2 deoxy-D-glucose labeled lipids was related to the expression of the transformed phenotype.     

Potassium fluxes and ouabain binding in growing,density-inhibited and rous sarcoma virus-transformed chicken embryo cells

Potassium fluxes, ouabain binding, and Na⁺ and K⁺ intracellular concentrations were determined for cultures of growing normal, density-inhibited and Rous sarcoma virus-transformed chicken embryo fibroblasts. No significant differences in K⁺ influx or ouabain binding were detected between growing normal cells and Rous sarcoma virus-transformed cells; however, ouabain binding and ouabain-sensitive K⁺ influx were 1.5- to 1.8-fold lower in density-inhibited cells. Thus, potassium influx in this system can be classified as a growth-related, but not transformation-specific change. As determined by both flame photometry and radioisotopic (⁴²K) equilibration, growing normal and density-inhibited cells had similar potassium contents, whereas transformed cells exhibited 1.4-fold higher potassium levels. Sodium ion levels, as measured by flame photometry, were also 2- to 4.5-fold higher in transformed than normal or density-inhibited cells. Complementary studies of potassium efflux showed a 1.3- to 1.5-fold higher rate (based on the percentage of pool exiting the cell) in growing normal versus density-inhibited or transformed fibroblasts. Because of the larger potassium pool in transformed cells, efflux based on absolute number of potassium ions is similar in normal and transformed chicken embryo fibroblasts.     

Insulin inhibition of protein degradation in cell monolayers

Protein degradation has been measured in confluent monolayers of eleven lines of contact-inhibited cells and ten transformed lines as the rate of release of trichloroacetic acid-soluble radioactivity after prelabeling cell protein with [³H]leucine. Insulin, at concentrations from 10^?12 M to 10^?6 M, has been added at the beginning of the 4-hour degradation period to detect selective effects of this hormone as an inhibitor of the inducible proteolysis occurring in serumfree medium. In addition insulin binding measurements have been performed on selected cell lines in an attempt to relate receptor properties to insulin action. Substantial effects of insulin are found in most cells with a selective inhibition at low insulin concentrations noted in several of the transformed lines. The difference in insulin sensitivity is not entirely definitive because temperature-sensitive transformation mutants of NRK cells are not more sensitive to insulin at a temperature where they show the transformed phenotype. Although insulin receptors on different cell lines have similar binding properties, two of the hepatomas used, H35 and MH₁C₁, show inhibition of protein degradation at insulin concentrations where receptor occupancy is extremely low. Calvarial osteoblast-like cells have a high rate of protein degradation which can be reduced by growth factors but not by insulin. The lack of an insulin response is a consequence of poor insulin binding to the cells. Insulin binds to the osteogenic sarcoma cells in substantial amounts. However, its normal action to inhibit the induced proteolysis is restricted because with these cells no increase of proteolysis occurs in serum-free medium. Generally higher rates of protein degradation are observed in the contact-inhibited lines than the transformed cells. We suggest that this difference may provide a selective growth advantage to transformed cells.     

Calcium effects on epidermal growth factor receptor-mediated endocytosis in normal and SV40-transformed human fibroblasts

Lowering of extracellular Ca²⁺ levels will reversibly arrest the growth of human fibroblasts (WI38). Simian virus₄₀(SV₄₀)-transformed WI38 cells do not exhibit this Ca²⁺-dependent arrest. One possibility for this difference in Ca²⁺ requirement is that extracellular or surface membrane-bound Ca²⁺ may be required for growth factor receptor-mediated endocytosis and this Ca²⁺ requirement may differ in normal versus transformed cells. In this study we have evaluated the role of Ca²⁺ in the binding, internalization, and degradation of epidermal growth factor (EGF) in the WI38 and SV₄₀ WI38 cell. The binding of [¹²⁵I]EGF to the cell surface is not significantly altered by lowering of Ca²⁺ to 10^?5-M levels in either the normal or transformed cell. At this Ca²⁺ level, growth of the normal cell is inhibited. The subsequent internalization of EGF is reduced nearly threefold in the normal cell but not in the transformed cell following Ca²⁺ deprivation. Degradation of the EGF-receptor complex is also sensitive to Ca²⁺. A twofold reduction in the rate of release of acid-soluble ¹²⁵I occurs in the normal but not the transformed cell under conditions of lowered medium Ca²⁺. In contrast, 2-chloro-10-3-aminopropyl phenothiazine (CP), an inhibitor of the Ca²⁺-dependent regulator protein calmodulin, causes an inhibition of [¹²⁵I]EGF internalization and degradation in both the normal and transformed WI38 cell, and a marked inhibition of [¹²⁵I]EGF binding to the cell surface receptor of the transformed cell but not the normal cell.     

Effect of low extracellular Ca2+ on growth spreading area,cytoplasmic Ca2+ concentration,and intracellular pH in normal and transformed human fibroblasts

The transformation of certain cells reduces the requirement of extracellular Ca²⁺ for growth. The SV-40 transformed human lung fibroblasts, WI-38 VA13, require less Ca²⁺ than normal WI-38 cells. Spreading area of normal cells decreases when cultured in 10 μM Ca²⁺ medium. Intracellular calcium concentration ([Ca²⁺]_i), of the normal and transformed cells cultured in 10μM and 2 mM Ca²⁺ media was measured by the fluorescence microscope technique using fura-2 as a probe. The [Ca²⁺], is measured in the resting state and during mobilization by serum or bradykinin stimulation. The lowering of extracellular calcium concentration results in a decrease in the resting state [Ca²⁺],_i of both normal and transformed cells. Although the total decrease in [Ca²⁺]_i is the same for both cell, the rate of decrease is much faster in normal cells than in transformed cells. Low extracellular Ca²⁺ reduces the number of cells responsive to the serum or bradykinin stimulation and decreases the peak [Ca²⁺]_i value in both cells. In addition, we investigated, using BCECF as a fluorecent probe, the intracellular pH (pH_i) of normal and transformed cells maintained at low and normal Ca²⁺. The low Ca²⁺ condition makes pH_i acidic in normal cells but not in transformed cells. The acidification of the normal cell is accompanied by a decrease in the spreading area of the cells. The decrease of the cell attacment, followed by the reduced spreading area, induced the acidic pH_i. These results suggest that the reduced Ca²⁺ requirement of transformed cells for growth is related to the mechanism of pH_i regulation rather than Ca²⁺ homeostasis and, possibly, to the anchorage-independent growth, which is a unique feature of transformed cells. © 1993 Wiley-Liss, Inc.     

External cell surface protein phosphorylation in normal and Rous sarcoma virus transformed chick embryo fibroblasts

Normal and Rous sarcoma virus (RSV)-transformed chick embryo fibroblasts growing on plastic dishes were incubated with ATP (γ³²P) in situ to detect external cell surface protein kinase activity. Under the conditions employed, ³²P was incorporated exclusively into proteins, specifically those at the external cell surface, as radioactivity was removed by tryspin treatment of labeled whole cells. In addition, exogenous histones were phosphorylated when added to the reaction mixture. Cyclic nucleotides had virtually no effect on ³²P incorporation, suggesting that little or no cyclic nucleotide-dependent protein kinase activity was present at the external cell surface. Cell surface protein kinase activity was higher in transformed than in normal cells, and, using a temperature-sensitive RSV src mutant, this difference was shown to be transformation-specific. Several differences were observed in the cell surface proteins phosphoryllated in normal and transformed cells and at least two of these were transformation-specific. These data suggest that changes in external cell surface protein physphorylation are associated with RSV transformation and thus could play a role in the formation of the transformed cell phenotype.     

Growth suppression of human transformed cells by treatment with bark extracts from a medicinal plant, Terminalia arjuna

Summary We have investigated the effects of acetone and methanol extracts of a medicinal plant, Terminalia arjuna, on the growth of human normal fibroblasts (WI-38), osteosarcoma (U2OS), and glioblastoma (U251) cells in vitro. We found that both extracts at 30 μg and 60 μg/ml concentrations inhibit the growth of transformed cells; the growth of normal cells was least affected. Although the transformed cells appeared to have fragmented nucleus by Hoechst staining, no deoxyribonucleic acid laddering effect was observed. In response to the extract treatment, the tumor suppressor protein, p53, was induced in U2OS but not in U251 and WI-38 cells. A cyclin-dependent kinase inhibitor, p21^WAF1, was induced in transformed cells only. The study suggests that the bark extract of medicinal plant, T. arjuna, has components that can induce growth arrest of transformed cells by p53-dependent and-independent pathways.     

Ornithine decarboxylase induction and the cytoskeleton in normal and transformed cells

ODC induction by fresh medium added to stationary, medium-depleted, confluent cultures has been studied in transformed HeLa and CHO cells, and in normal human fibroblasts as an indicator of the resumption of cell multiplication. The transformed HeLa cell displays a more easily reversed G₁ block, a higher peak ODC level, and a shorter time period for achievement of the peak ODC value than does the normal fibroblast. Low concentrations of microtubule depolymerizing agents like colchicine suppress ODC induction almost completely in the normal fibroblast, but hardly at all in the HeLa or CHO cells. Both transformed cells occasionally reveal a superinduction of ODC at very low colchicine levels (10^?8-10^?7 M) and a more variable response to such agents than does the normal fibroblast. Higher concentrations of colchicine suppress ODC induction in all cells. Experiments with actinomycin D and cycloheximide indicate that the principal colchicine action involves inhibition at the level of protein or mRNA synthesis, rather than inactivation of the already synthesized enzyme. These experiments are provisionally interpreted as an indication that a microtubular system is needed to reinitiate certain steps associated with growth in G₁-blocked, normal cells, and that a second microtubular action terminating enzyme biosynthesis may exist. This microtubular control is defective in the transformed cells here studied. Specific microtubular actions necessary for initiation and termination of protein syntheses may occur throughout the cell reproductive cycle, and in the course of normal differentiation processes.     

Vimentin-derived proteins : Differences between normal human fibroblasts and transformed human cells

Two-dimensional gel electrophoresis revealed a quantitative difference in a series of polypeptides ranging in MW from 45 000 to 51 000 and of lower isoelectric pH than vimentin, when comparing normal human fibroblasts with a virally transformed subline and with HeLa cells. Re-extraction of purified [³⁵S]vimentin with cold whole cell homogenates and peptide mapping showed that these polypeptides are derivatives of vimentin. They may be natural components of a normal fibroblast's architecture or they may arise from a pool of vimentin that is not structured within intermediate filaments at the time of extraction. Furthermore, we show that vimentin from the two transformed cell types is more resistant to proteolysis by whole cell homogenates than vimentin from normal fibroblasts. Structural alteration of vimentin may play an important role in the expression of transformation.     

Surface Alterations of Cells Carrying RNA Tumour Virus Genetic Information

CELLS transformed by the DNA tumour viruses, polyoma virus and SV40, are agglutinated by lectins such as wheat germ agglutinin¹, concanavalin A (Con A)² and soybean agglutinin³. Agglutination in these cases presumably reflects changes in the cell surface related to the transformed properties of the cell; studies with a temperature-dependent mutant of polyoma virus has shown that cell surface changes are controlled by viral genes⁴. Here we describe experiments in which we investigated the agglutinability of cells transformed by RNA tumour viruses. One recent report had suggested that cells transformed by RNA tumour viruses were not specifically agglutinated⁵, whereas a second more recent report claimed the specific agglutination of cells transformed by RSV⁶. We find that transformed rat, mouse and cat cells that replicate the sarcoma-leukaemia virus complex of murine (MSV) and feline (FeSV) origin are strongly agglutinated by Con A, but mouse and human cells that replicate the murine and feline leukaemia virus components alone are not agglutinated. The ability to agglutinate is rapidly acquired by normal mouse cells on infection with the murine sarcoma virus at a rate that parallels virus replication. In contrast to the results obtained with cells producing virus, non-virus-producing transformed hamster and mouse cells that synthesize virus-specific RNA are either not agglutinated or are agglutinated to a lesser degree. These results suggest that the cell surface alterations responsible for agglutination are not necessarily associated with the transformed state of the cell, but rather with the possession of sarcoma virus-specific information.     

Chemical and immunological studies of cell surfaces from normal and transformed cells

Immunological and chemical studies of cell surfaces from normal and transformed BALB/c fibroblasts have shown alterations associated with transformation. The cells studied include normal lines which do not cause tumors when injected into BALB/c mice, viral transformants, and spontaneous transformants which cause tumors that either regress or grow progressively, killing the host. The spontaneously transformed progressors include cell lines which are immunogenic and nonimmunogenic as determined by the ability of tumor excision to protect an animal from subsequent rechallenge by tumor cells. Tumor-bearing mice produce lymphocytes which are nonspecifically cytotoxic for all the normal and transformed lines. Some of the cell lines induce specific antibody formation in BALB/c hosts. Antisera have been prepared in rabbits which are specific for the transformed cell lines. These antisera can be used to determine specific surface changes on the transformed cells. Chemical studies have shown glycolipid alterations between the normal cells and some, but not all, of the transformants. Glycoproteins labeled by lactoperoxidase-¹²⁵ I or [³H] glucosamine were compared by SDS gel electrophoresis. Results from these studies do not show changes associated with malignancy. Individual glycoprotein regions from gels were treated with pronase, and the glycopeptides compared by Sephadex G-50 chromatography. Alterations in glycopeptides from several cellular glycoproteins are the only changes which appear to be associated with malignancy.     

Correlation of (Na---K)-ATPase activity with growth of normal and transformed cells

The (Na⁺---K⁺)-stimulated Mg²⁺-dependent ATPase activities of 3T3 and SV40 transformed 3T3 cells were compared as a function of cell population density. For normal cells the enzyme activity remained relatively constant during exponential growth, but decreased sharply coincident with contact inhibition of growth at confluence. This decrease in activity could be reversed by stimulating contact-inhibited cultures to undertake renewed short-term growth either by adding fetal calf serum or changing the medium completely. Transformed cells did not experience a decrease in (Na⁺---K⁺)-ATPase activity upon reaching confluence, but this is consistent with the fact that they were still growing exponentially at this stage. However, non-confluent cultures of both normal and transformed cells incurred a marked decrease in levels of the enzyme when growth was inhibited by serum depletion. The results have been interpreted as indicating that levels of (Na⁺---K⁺)-ATPase in both normal and transformed cells are correlated with growth. Hence the different patterns of ATPase activity displayed by malignant cells and their normal counterparts with increase in cell number appear to be a reflection of their dissimilar growth behaviours rather than of any innate difference between them.     

Properties of the genome in normal and SV40 transformed WI38 human diploid fibroblasts. I. Composition and metabolism of nonhistone chromosomal proteins.

The composition and metabolism of nonhistone chromosomal proteins associated with the genome of normal and SV40 transformed WI38 human diploid fibroblasts were examined. Evidence is presented which indicates variations in the relative protein content, specific activity and phosphorylation of several defined molecular weight classes of these chromosomal polypeptides. In addition, it is shown that blocking DNA replication with cytosine arabinoside does not inhibit the incorporation of ³H-leucine into nonhistone chromosomal proteins of SV40 transformed cells. The possibility that the nonhistone chromosomal proteins of human diploid fibroblasts transformed by SV40 virus may be involved in the regulation of viral induced alterations in gene expression is discussed.     

Agglutination of Normal and Rous Sarcoma Virus-transformed Chick Embryo Cells by Concanavalin A and Wheat Germ Agglutinin

RODENT cells in culture transformed by oncogenic DNA viruses have surface sites that on normal cells are usually present in latent form only^1,2. This difference in surface properties can be detected by plant glycoproteins such as wheat germ agglutinin (WGA) and concanavalin A (Con A), which agglutinate only transformed cells, because they have certain carbohydrate moieties on their neoplastic surfaces^1–4. According to some investigators, normal and neoplastic cells that have been freshly isolated also exhibit this marked difference^3,5; according to others^6,7, there is no such distinction. We have looked for such differences in cells transformed by RNA tumour viruses and in several types of normal and naturally occurring malignant cells and their normal counterparts.     

Effect of proteolytic inhibitors on growth and surface architecture of normal and transformed cells

Protease inhibitors were tested for their effect on the growth of normal and SV40-transformed mouse fibroblasts. The protease inhibitors TAME¹ and EWTI¹, which act competitively on proteases, reduce the growth of transformed cells more than that of untransformed parent cells. However, transformed cells grown in medium containing these drugs do not show contact inhibition of cell division or decreased agglutinability with Concanavalin A. The inhibition of growth is due to an extended duration of all phases of the cell cycle. The protease inhibitor TLCK¹, an active site titrant reacting irreversibly with trypsin, blocks transformed cells in the premitotic stage of the cell cycle. This effect does not occur in the untransformed parent cells. The decrease in agglutinability of transformed cells treated with TLCK is correlated with a partial synchronisation in the G2 stage of the cell cycle. Our results do not support the hypothesis that protease inhibitors induce transformed cells to assume a normal growth pattern and that this is accompanied by a decreased agglutinability with plant lectins.     

Protein synthesis in transformed 3T3 cells permeabilized by exogenous ATP

Exogenous ATP has been shown to cause a rapid and reversible increase in permeability in transformed 3T3 cells (3T6 and SV3T3) but not in untransformed 3T3 cells. The cells remain viable, but lose intracellular acid-soluble pools. Treatment of transformed cells with ATP greatly reduces incorporation of ¹⁴C-leucine into protein, which is restored by the incubation of the cells with Dulbecco's modified Eagle's medium or by the external additions of certain ions and energy sources. tRNA is not required for the restoration of protein synthesis. In the permeabilized cells the energy for protein synthesis can be provided by glycolysis, oxidative phosphorylation, or direct addition of ATP. These studies demonstrate the usefulness of this method for studying the control of metabolism and macromolecular synthesis in monolayer cultures of transformed mammalian cells.     

Properties of the genome in normal and SV-40 transformed WI-38 human diploid fibroblasts. III. Turnover of nonhisone chromosomal proteins and their phosphate groups.

The turnover of nonhistone chromosomal proteins and their phosphate groups was compared in normal and in SV-40 virus transformed WI-38 human diploid fibroblasts. Cells were pulse labelled with tryptophan-³H and ³²P for 30 minutes and the specific activities of tryptophan-³H and ³²P in the various molecular weight classes of nonhistone chromosomal proteins were determined during the first four hours following termination of labelling. While a rapid turnover of high molecular weight nonhistone polypeptides (142, 000 to 200, 000 Daltons) is evident after one hour in SV_40 transformed cells, the specific activities of these nonhistone chromosomal polypeptides are not significantly decreased in normal cells. In contrast, a rapid turnover of low molecular weight (30, 000 to 51, 000 Daltons) nonhistone chromosomal proteins occurs during the first hour in normal WI-38 cells with no corresponding decrease in the specific activities of these proteins in SV-40 transformed cells. There is no apparent net turnover of phosphate groups on nonhistone chromosomal proteins in either normal or SV-40 transformed cells four hours following pulse labelling. Rather, during the first four hours significant fluctuations are observed in the ³²P specific activities of defined molecular weight fractions. Taken together with previous reports of differences in the composition, synthesis and phosphorylation of nonhistone chromosomal proteins in normal and SV-40 transformed human diploid cells the present results further indicate the complex nature of the alterations in these proteins which accompany viral transformation.